palladium(II), dichloro[bis(diphenylphosphino ... - ACS Publications

Jan 7, 1976 - course would be zero in an ideal square-planar arrangement. C(4a). Figure 3. View ofthe ...... 2-methoxy-3-A',vV-dimethylaminopropyl; Mb...
0 downloads 0 Views 1MB Size
2432 Inorganic Chemistry, Vol. 15, No. 10, 1976

W. L. Steffen and Gus J. Palenik

vironments which might be responsible for the different conformations observed. For the dtt group the nonbonded interactions are weaker (no aromatic C-C distances below 3.70 A) and thus we believe that the dtt geometry is scarcely influenced by the crystal packing. Conclusions The essential results of this structural investigation are (i) in transition metal square-planar complexes of 1,3-diaryltriazenido acting as a monodentate ligand, there is no interaction between the i~ electrons of the ligand and the metal, and (ii) the most likely intramolecular mechanism responsible for the fluxional behavior is through an intermediate fivecoordinate 18-electron structure formed by a u interaction between the lone pair belonging to the terminal nonbonded nitrogen atom and the metal (see Scheme I). The short Pd-sN(3) distance (2.836 A) and the planarity of the PdN(l)-N(2)-N(3) system make possible the formation of the intermediate species with a moderate rearrangement of the ligand. Registry No. PdCl(PPh&dtt, 5967 1-96-4. Supplementary Material Available: Listing of structure factor amplitudes (26 pages). Ordering information is given on any current masthead page.

References and Notes (1) (a) Laboratorio di Chimica e Tecnologia dei Radioelementi del CNR.

(b) Istituto di Chimica delle Macromolecole del CNR. (c) Istituto di Chimica Generale ed Inorganica, Universita di Padova. (2) P. F. Dwyer and D. P. Mellor, J . A m . Chem. SOC.,63, 81 (1941). (3) M. Corbett, B. F. Hoskins, and N. J. McLeod, Chem. Commun., 1602 (1968). (4) I. D. Brown and J. D. Dunitz, Acta Crystallogr., 14, 480 (1961). (5) C. M. Harris, B. F. Hoskins, and R. L. Martin, J . Chem. Soc., 3728 (1959). (6) P. Hendricks, K. Olie, and K. Vrieze, submitted for publication. (7) S. Candeloro de Sanctis, pi. V. Pavel, L. Toniolo, J . Organometal. Chem., 108, 409 (1976). (8) M. Corbett and B. F. Hoskins, J . A m . Chem. Soc., 89, 1530 (1967). (9) L. ’I’oniolo, A. Immirzi, U. Croatto, and G. Bombieri, Inorg. Chim. Acta, 19, 209 (1976). (10) W. R. Busing and H . A. Levy, Acta Crystallogr., 10, 180 (1957). (1 1) J. M. Stewart, F. A. Kundell, and J. C. Baldwin, “X-Ray 70 System” crystallographic program, version of July 1970, University of Maryland. (12) D. T. Cromer and J. T. Waber, Acta Crystallogr., 18, 104 (1965). (13) D. T. Cromer and D. Libermann, J . Chem. Phys., 53, 1891 (1970). (14) C. K . Johnson, “ORTEP”, Report ORNL 3794, Oak Ridge National Laboratory, Oak Ridge, Tenn., 1965. (1 5) M. G. B. Drew, M. J. Riede, and J. Rcdgers, J. Chem. Soc., Dalton Trans., 234 (1972). (16) G. Beran, A. J. Carty, P. C. Chieh, and H. A. Patel, J . Chem. Soc., Dalton Trans., 488 (1973), and references therein. (17) (a) V. F. Gladkova and Yu. D. Kondrashev, Kristallografya, 17, 33 (1972); (b) ibid., 16, 929 (1971). (18) Yu. A. Omel’chenko and Yu. D. Kondrashev, Kristallografya, 17,947 ( 1972). (19) G. J. Palenik, Acta Crystallogr., 16, 596 (1963). (20) J. J. Daly, J . Chem. SOC.,3799 (1964). (21) C. P. Brock and J. A. Ibers, Acta Crystallogr., Sect. E, 29, 2426 (1973). (22) R. W. G. Wyckoff “Crystal Structures”, Vol. I, Interscience, New York, N.Y., 1963, p 26.

Contribution from the Center for Molecular Structure, Department of Chemistry, University of Florida, Gainesville, Florida 3261 1

Crystal and Molecular Structures of Dichloro [bis(diphenylphosphino)methane] palladium(II), Dichloro [bis(dipheny1phosphino)ethanel palladium(II), and Dichloro [ 1,3-bis(diphenylphosphino)propane]palladium(I1) W. L. STEFFEN’ and GUS J. PALENIK* Received January 7 , 1976 AIC60004M The synthesis and crystal structure determination of three palladium chloride-diphosphine complexes are reported. The PdC12(dpm) complex (dpm is bis(dipheny1phosphino)methane) forms monoclinic crystals with unit cell dimensions of a = 11.372 (3), b = 12.273 (3), and c = 17.498 (8) A, with p = 100.27 (3)’ and space group P21/n. The PdClz(dpe) complex (dpe is bis(dipheny1phosphino)ethane) forms monoclinic crystals with one molecule of CH2C12 incorporated in the lattice. The space group is P21/c and the cell dimensions are a = 12.290 (8), b = 15.495 (9), and c = 15.403 (12) A, with p 104.70 (5) ’. The PdC12(dpp) complex (dpp is bis(dipheny1phosphino)propane) forms triclinic crystals of space group P1 with cell dimensions of a = 10.633 (3), b = 11.525 (2), and c = 14.461 (5) 8, and CY = 95.97 (2), p = 91.31 (3), and y = 134.90 (1)’. The structures were solved by the heavy-atom method and refined by least-squares techniques to unweighted R values of 0.024 for dpm, 0.047 for dpe, and 0.027 for dpp. The three complexes differ in the number of CH2 groups between the two phosphorus atoms of the ligand, causing the P-Pd-P angle to change from 72.68 (3)’ (dpm complex) to 85.82 (7)’ (dpe complex) to 90.58 (5)’ (dpp complex). The Pd-P distances [2.234 (1) and 2.250 (1) A in dpm, 2.233 (2) and 2.226 (2) A in dpe, and 2.244 (1) and 2.249 (2) 8, in dpp] neither are equal nor vary systematically with the alkyl chain length. Similarly, the Pd-Cl distances [2.362 (1) and 2.352 (1) A, 2.361 (2) and 2.357 (2) A, 2.351 (1) and 2.358 (2) 8, in the dpm, dpe, and dpp complexes respectively] are not equal in the three complexes. The results of the three structure determinations are discussed in terms of the steric problems inherent in a bidentate chelating ligand.

Introduction The relative importance of steric vs. electronic effects in coordination complexes is difficult to determine. Changes in the electronic properties of ligands invariably involve altering the steric requirements and vice versa. For example, in the series of M(CNS)L2 complexes, where M = Pd or Pt, C N S is used for the thiocyanate ion without specifying the mode of coordination, and L is PPh3, AsPh3, or SbPh3, the steric and electronic factors operate in the same direction.* Therefore, changes in the mode of thiocyanate coordination in the above series of complexes could be interpreted as either

an electronic or a steric effect depending on one’s preference. We attempted to separate the steric from electronic factors in thiocyanate coordination by considering the series Pd( C N S ) ~ [ P ~ ~ P ( C H Z ) ~ Pwhere P ~ Z n] ,= 1, 2, or 3.3 We observed that the coordination changed from S,S when n = 1 to N,S for n = 2 and N,N in the n = 3 case and seemed to parallel the steric influence. Although we assumed that the electronic properties of the diphosphine would be approximately constant, the fact that the P-Pd-P angle changed from 13.3 to 89.3’ raised the question of whether our assumption was ~ a l i d . ~Furthermore, ,~ the very short Pd-P distance in

Palladium Chloride-Diphosphine Complexes

Inorganic Chemistry, Vol. 15, No. 10, I976 2433 Table 11. Scheme of Refinement

Table I. Crystal Data -~

Crystal system Space group a, A b, A c. A ff, deg A deg 7,deg VOl, A3 Mol wt Z p(calcd3), g/cm dmeasd), g/cm3 Crystal size, mm Recrystallizn solvent Method of data collection

PdCl, (dprn)

PdC1, (dpe). CH,Cl,

PdCl, (dpp)

Monoclinic P2, In 11.372 (3) 12.273 (3) 17.498 (8)

Monoclinic p2, I C 12.290 (8) 15.495 (9) 15.403 (12)

100.27 (3)

104.70 (5)

2402.8 561.7 4 1.553

2837.1 660.6 4 1.547

Triclinic P1 10.633 (3) 11.525 (2) 14.461 (5) 95.97 (2) 91.31 (3) 134.90 (1) 1236.7 589.8 2 1.584

1.556

1.566

1.578

0.33 X 0.31 0.26 Acetonitrile

X

Moving crystal, moving counter Radiation used Mo Ka 11.2 M, an-* 0-45 28 range, deg No. of unique 3159 reflections No. of obsd 2855 reflections

0.35 X 0.19 X 0.54 X 0.39 X 0.10 0.21 CH,Cl, /hexane Chloroform Moving crystal, moving counter Mo Ka 11.4 0-45 3750

Moving crystal, moving counter Mo Ka 10.9 0-45 325 1

2885

2954

the PdCl2[Ph2PN(C2Hs)PPh2l6 complex suggested that the electronic factors might vary as a function of the P-Pd-P angle. Therefore, we undertook a study of the corresponding PdC12[Ph2P(CH2),PPh2] complexes so that changes in the diphosphine ligand could be studied with a constant group opposite the phosphorus atoms. Our results suggest that although there are small, nonsystematic changes in the Pd-P distances, our earlier conclusions remain valid. Experimental Section Materials. The three diphosphines were obtained from Pressure Chemical Corp. and were used as supplied. The other chemicals were all reagent grade or equivalent. Preparation of the Complexes C12Pd[Ph2P(CH2),PPh2], n = 1,2, and 3. The bis(benzonitri1e)palladium chloride complex was prepared by the published method’ and then reacted with a stoichiometric amount of the diphosphine ligand.s The microanalyses of all three compounds were performed by Galbraith Laboratories, Inc., Knoxville, Tenn. The melting points were taken in open capillaries with a Mel-temp apparatus and are uncorrected. Crystals suitable for diffraction studies were grown by slow cooling and evaporation, using the solvents given in Table I. Anal. Calcd for PdClz(dpm), PdC25H22P~C12:C, 53.46; H, 3.95; CI, 12.62. Found: C, 53.25; H, 3.95; C1, 12.82; mp 310 “C. Calcd for PdCl~(dpe),PdC26H292C12: C, 54.24; H, 4.20; C1, 12.32. Found: C, 53.98; H, 4.14; C1, 12.42; mp >360 “C. Calcd for PdClz(dpp), PdC27H26P2C12: C, 54.99; H, 4.44; C1, 12.02. Found: C, 54.79; H, 4.57; C1, 11.86; mp 335 “C. Data Collection and Reduction. Preliminary precession and Weissenberg photographs were taken of all three compounds to determine the space groups and approximate unit cell dimensions. A different crystal was selected for the determination of precise ceiJ constants and the measurement of the intensity data. A Syntex P1 diffractometer was utilized for these measurements. The pertinent crystal data and details of the intensity measurements are summarized in Table I. The abbreviations used in Table I and in the remainder of the paper are dpm = (C6H5)2PCH2P(C6H5)2, dpe = (C6H5)2PCH2CH2P(C6H5)2, and dpp = (C6H5)2PCH2CH2CH2P(C6H5)2. These abbreviations and the experimental details of the data collection are identical with those previously reported.3 The criteria for “reliable” reflections were Z > 2.00(Z) for the dpm and _dpe complexes and Z > 1 . 8 4 for the dpp case. The space group P1 for the dpp complex was chosen on the basis of the intensity statistic^.^ No absorption

R index with all atoms from Fourier syntheses Refinement with isotropic thermal parameters R index Refinement with anisotropic thermal parameters R index Refinement with hydrogen atoms included but not refined R index (final) Flow for weighting scheme F h e h for weighting scheme

PdC1,- PdCl,(dpe). PdC1,(dpm) CH,Cl, (dw) 0.14 0.18 0.21 3 cycles

3 cycles

3 cycles

0.070 3 cycles

0.110 3 cycles

0.074 3 cycles

0.042 6 cycles

0.066 6 cycles

0.044 6 cycles

0.024 12.0 48.0

0.047 25.0 75.0

0.027 30.0 100.0

Figure 1. View of the PdCl,(dpm) molecule, showing the atomic numbering and thermal ellipsoids. corrections were applied because of the relatively small value of p. Structure Determination and Refmement. All three structures were solved by the heavy-atom method and refined by least-squares techniques. The details are summarized in Table 11; the procedures are similar to those previously reported.3 The scattering factor for Pd was taken from Cromer, Larson and Waber’s compilation,10 while the factors for CI, P, and C were from Hanson, Herman, Lea, and Skillman.ll The hydrogen scattering curve was from Stewart, Davidson, and Simpson.12 The final atomic parameters for the nonhydrogen atoms are given in Table 111-V. The hydrogen atom parameters are presented in Tables VI-VIII. The tables of observed and calculated structure amplitudes are available.’3

Results and Discussion The three complexes are illustrated in Figures 1-3 and are discrete molecular species. The Pd atom is in the center of the approximately square-planar arrangement of the two phosphorus and two chlorine atoms. The chlorine atoms are cis as required by the geometry of the bidentate chelating diphosphine ligand. Individual bond distances and angles in the three complexes are given in Tables IX and X, except for the bond distances and C-C-C bond angles in the four phenyl rings, not included but available. The three complexes differ only in the length of the alkyl chain between the two phosphorus atoms of the diphosphine ligand. There is no reason to expect the Lewis basicity of the phosphorus atoms in the three ligands to differ in the absence of steric factors. Therefore, the variations in Pd-P distances in the three complexes were somewhat surprising. The Pd-P distances are significantly different in the dpm complex (to

2434 Inorganic Chemistry, Vol. 15, No. 10, 1976

W. L. Steffen and Gus J. Palenik

Table 111. Final Parameters of Nonhydrogen Atoms in PdC1, (dpm) Atom

X

56 369 (2) 5 273 (1) 4 168 (1) 6 092 (1) 7 244 (1) 7 058 (3) 6 960 (3) 6 496 (3) 7 137 (4) 8 240 (4) 8 700 (4) 8 070 (3) 4 909 (3) 3 768 (3) 2 877 (4) 3 112 (4) 4 235 (5) 5 151 (4) 7 450 (3) 7 007 (3) 7 214 (4) 7 857 (4) 8 295 (4) 8 100 (4) 8 615 (3) 8 549 (3) 9 601 (4) 10 684 (4) 10 747 (3) 9 720 (3) a

Y

Z

37 850 (2) 5 235 (1) 4 363 (1) 2 278 (1) 3 032 (1) 1 7 1 1 (3) 2 444 (3) 3 073 (3) 3 216 (3) 2 733 (4) 2 106 (4) 1 9 5 8 (3) 1 3 2 3 (3) 1 5 1 7 (3) 758 (4) -181 (4) -390 (4) 369 (3) 2 783 (3) 3 505 (3) 3 304 (4) 2 408 (4) 1 6 8 5 (4) 1 8 5 8 (3) 3 624 (3) 4 381 (3) 4 810 (3) 4 489 (4) 3 744 (4) 3 312 (4)

27 431 (1) 1 845 (1) 3 444 (1) 3 451 ( 0 ) 2 366 (0) 2 815 (2) 4 414 (2) 4 941 (2) 5 688 (2) 5 893 (2) 5 385 (3) 4 626 (2) 3 504 (2) 3 092 (2) 3 090 (2) 3 499 (3) 3 922 (3) 3 925 (2) 1382(2) 796 (2) 41 (2) -106 (2) 475 (3) 1 225 (2) 2 887 (2) 3 470 (2) 3 896 (2) 3 746 (3) 3 179 (3) 2 746 (2)

Allvalues are X l o 4 except those for Pd, which are X 10'

P11

P22

P33

P i2

013

P23

47 (3) 6 (1) 63 (1) 0 (1) -7 (1) 0 (4) -9 (4) 12 ( 5 ) -16 (7) -44 (7) 32 (7) 36 (6) -23 (4) -28 ( 5 ) -67 (6) -135 (8) -80 (8) -43 (6) -37 ( 5 ) -14 (6) -34 (8) -67 (8) -37 (7) -21 (6) -11 (4) -14 ( 5 ) -36 (6) -55 (6) -33 (7) -10 (6) The estimated standard deviations are given in parentheses. The temperature

C(3 (6b)

Figure 2. View of the PdCl,(dpe) molecule, showing the atomic numbering and thermal ellipsoids.

= (11 - 1 2 ) / ( q 2 - (r22)1/2 = 11.3), and the differences are possibly significant ( t o = 2.47 for dpe and 2.23 for the dpp) in the other two complexes. The variations in the Pd-P distances can be rationalized if we consider the steric problems involved in having a cis-bidentate chelating ligand. A view down the C(1)-P(l) bond in PdC12(dpm) and down the C(2)-C(3) bond in PdC12(dpp) is given in Figure 4. In both the dpm and dpp complexes appreciable eclipsing of bonds is required if both phosphorus atoms are to bond to the same palladium atom. The dpe case where the bonds are staggered has not been shown. The steric strain is also indicated in the bond angles in the alkyl chain which show large deviations from ideality in the dpm and dpp cases while the angles are nearly tetrahedral in the dpe complex. Finally, one can consider the displacements of the two phosphorus atoms from the plane defined by the Pd and the two C1 atoms, which of course would be zero in an ideal square-planar arrangement.

Figure 3. View of the PdCl,(dpp) molecule, showing the atomic numbering and thermal ellipsoids.

The deviations of P(1) and P(2) from the PdC12 plane are -0.136 and +0.242 in the dpm case, -0.070 and +0.087 A in the dpe complex, and -0.053 and +0.312 when dpp is the ligand. In summary we see that the dpe ligand appears to form the least strained complex and the one which is the nearest to an ideal square-planar arrangement. The two Pd-P distances in the relatively strain-free dpe complex are significantly shorter than the Pd-P bonds in the dpp case. In both complexes, the differences in the individual Pd-P distances are possibly significant but the differences are small and the average value can probably be used. Therefore, we see that there is an increase in the Pd-P distances (average 2.230 A for dpe and 2.246 A for dpp) in going from the dpe to dpp complex, in agreement with an increase in strain in the latter case. An analysis of the dpm Pd-P distances is complicated by the fact that the difference in the two Pd-P bond lengths is highly significant. The shorter Pd-P( 1) distance

Inorganic Chemistry, Vol. IS, No. IO, I976 2435

Palladium Chloride-Diphosphine Complexes Table IV. Final Parameters of Nonhydrogen Atoms in PdCla(dpe)-CHzC12a Atom

Y

X

z

Pzz

PI I

PlZ

033

Pl3

P23

215 (4) Pd 22 116 (5) 30 670 (3) 37 299 (3) 618 (4) 26 (5) 49 (7) -27 (2) 3 729 (1) 2 731 (1) 37 (2) Cl(1) 3 130 (2) 12 (2) 88 (2) 3 029 (1) 3 656 (1) 70 (2) 8 (2) Cl(2) 438 (2) 7 (2) 27 (2) 2 360 (1) 4 701 (1) P(1) 1 4 6 2 (2) 4 (2) 24 (2) 1(1) 59 (2) 2 512 (1) 4 493 (1) P(2) 3 846 (2) 19 (2) 1(2) 2 (2) 56 (2) 1 614 (5) 5 346 (5) 27 (8) 11 (6) C(1) 2 517 (6) 3 (7) 66 (6) 2 063 (5) 5 548 (5) 14 (8) 16 (7) C(2) 3 646 (6) 14 (9) 73 (6) 1 7 1 3 (4) 4 260 (4) C(la) 220 (6) -9 (7) -1 (5) 35 (7) 63 (6) -25 (8) -24 (10) 61 (10) 862 (6) 4 012 (6) C(2a) 305 (7) 95 (8) 142 (11) 88 (12) -37 (8) -73 (12) 381 (6) 3 626 (6) C(3a) -662 (9) 47 (11) -35 (9) 104 (9) 741 (7) 3 493 (6) -75 (12) C(4a) -1 691 (8) -17 (11) 19 (12) -29 (12) 1 5 8 7 (7) 3 713 (7) C(5a) -1 797 (8) 76 (8) 30 (11) -16 (9) -23 (10) 2 079 (6) 4 108 (6) C(6a) -846 (7) 86 (8) 3 084 (5) 5 510 (4) C(1b) 1 1 1 8 (5) -4 (6) 59 (6) 10 (8) 22 (7) 2 770 (5) 101 (8) 6 220 (5) C(2b) 744 (7) 3 (6) 8 (8) 56 (9) 61 (10) 19 (11) 6 806 (5) 124 (9) 3 334 (6) C(3b) 443 (8) 4 (7) 60 (11) 30 (11) 151 (11) 4 212 (6) ' 6 712 (5) C(4b) 528 (8) -6 (7) 78 (12) 11 (10) 149 (11) 4 524 (5) 6 014 (6) C(5b) 920 (8) 6 (7) 122 (9) 66 (10) 3 965 (5) 5 410 (5) C(6b) 1 207 (8) 7 (9) -3 (6) 3 221 (5) 4 815 (5) C(1c) 5 047 (6) 70 (6) -4 (9) 10 (8) 7 (7) -42 (10) 167 (13) -112 (15) 63 (14) 5 525 (7) 3 772 (7) C(2c) 5 138 (10) -118 (20) -46 (13) 234 (18) 61 (18) 5 795 (8) 4 298 (8) C(3c) 6 097 (12) 135 (12) -83 (16) -15 (17) 4 299 (8) 5 390 (9) C(4c) 6 906 (10) 5 (14) -23 (16) 139 (20) -72 (16) 126 (131 4 635 (10) 3 790 (8) C(5c) 6 789 (10) -27 (11) 98 (14) 112 (10) -62 (13) 4 332 (7) 3 258 (7) C(6c) 5 824 (8) 3 914 (5) 1 605 (5) C(1d) 4 265 (6) 6 (6) 55 (6) 2 (7) 29 (8) 31 (10) 36 (11) 1 096 (6) 4 297 (6) 9 (8) C(2d) 5 176 (7) 89 (8) 28 (10) 48 (11) 80 (13) 3 873 (7) 413 (6) C(3d) 5 504 (8) 90 (9) -7 (10) 27 (12) 110 (14) 216 (6) 3 024 (7) 124 (10) C(4d) 4 908 (9) 29 (14) -31 (9) 46 (13) 168 (12) 2 613 (6) 692 (7) C(5d) 4 001 (10) 24 (11) 1 402 (6) -20 (8) 34 (11) 3 050 (6) 105 (9) C(6d) 3 651 (8) 117 (8) 167 (4) 3 180 (4) 2 066 (3) Cl(3) 6 606 (4) 65 (7) 36 (6) 164 (28) 83 (25) 62 (23) 3 038 (13) 1 7 0 0 (12) 102 (12) C(3) 7 746 (11) 139 (8) -156 (10) -72 (7) 3 828 (5) 969 (3) 183 (5) Cl(4) 7 950 (4) a All values are X l o 4 except those for Pd, which are X 10'. The estimated standard deviations are given in parentheses. The temperature factor is of the form exp[-(pl,ha + 02&' + f13J2 + p12hk+ o I 3 h l +02&Z)].

Table V. Final Parameters of Nonhydrogen Atoms in PdCl,(dpp)= Atom

X

Y

z

011

Pa2

P33

01z

PI3

P23

Pd 6555 (4) 24 529 (2) 40 143 (4) 1059 (5) 848 (4) 1348 (8) 6 522 (1) 2 329 (1) 183 (4) Cl(1) 1548 (1) 164 (2) 92 (2) 5 413 (1) 2 724 (1) 128 (3) Cl(2) 3674 (1) 95 (2) 105 (2) 1 7 4 1 (1) 2 791 (1) 138 (3) P(1) -113 (1) llO(2) 84 (2) 2 592 (1) 2 162 (1) P(2) -2251 (1) 146 (3) 105 (2) 97 (2) -131 (5) 2 675 (3) 135 (14) C(1) -2506 (5) 137 (9) 89 (7) 1 720 (3) 167 (10) 114 (8) -590 (5) C(2) -3463 (6) 165 (16) 1 4 8 5 (3) 480 (5) C(3) -3735 (6) 155 (9) 127 (7) 181 (15) 2 072 (3) 1 057 (5) 127 (8) 102 (7) C(1a) 707 (5) 166 (13) -221 (6) 329 (14) 207 (10) 2 299 (4) C(2a) 483 (7) 453 (22) 1 7 1 9 (4) -823 (7) 352 (14) 226 (11) C(3a) 988 (8) 507 (24) -167 (7) 940 (4) 256 (13) 228 (11) C(4a) 1734 (7) 380 (22) 1 0 9 1 (7) 712 (4) C(5a) 1951 (7) 272 (13) 189 (10) 297 (21) 1 699 (5) 1 278 (3) C(6a) 1432 (6) 194 (10) 126 (8) 218 (16) 2 130 (5) 4 008 (3) C(1b) 730(5) 170 (13) 149 (8) 95 (6) 4 258 (3) 186 (10) 180 (9) 2 661 (6) C(2b) 2352 (6) 270 (17) 3 055 (6) 5 194 (4) 182 (10) 178 (9) 248 (18) C(3b) 3017 (6) 2 951 (6) C(4b) 2119 (7) 5 883 (3) 289 (19) 252 (12) 183 (9) 2 424 (7) C(5b) 494 (7) 5 646 (3) 293 (14) 252 (12) 377 (23) 2 003 (6) 4 708 (3) C(6b) -202 (6) 187 (10) 216 (10) 289 (18) C(lc) -2679 (5) 1 469 (3) 3 542 (5) 117 (8) 131 (7) 168 (14) 3 725 (6) 563 (3) C(2c) -2253 (6) 199 (10) 196 (9) 292 (18) 4 446 (6) C(3c) -2570 (7) 224 (11) 234 (11) 317 (20) 17 (3) 4 999 (7) 389 (4) C(4c) -3260 (7) 205 (11) 233 (11) 332 (20) 4 848 (6) 1 2 9 1 (4) C(5c) -3671 (7) 222 (11) 232 (10) 378 (20) C(6c) -3391 (6) 4 102 (6) 177 (9) 174 (8) 1 825 (3) 277 (16) C(1d) -3139 (5) 3 259 (3) 2 399 (5) 108 (7) 113 (7) 164 (13) 3 996 (3) 3 677 (6) C(2d) -2062 (6) 169 (10) 142 (8) 150 (16) 3 558 (7) C(3d) -2693 (7) 4 850 (3) 274 (13) 208 (10) 314 (21) 2 182 (7) C(4d) -4332 (8) 4 979 (4) 320 (14) 254 (12) 446 (24) 4 242 (4) 886 (7) C(5d) -5422 (8) 212 (13) 236 (12) 188 (22) C(6d) -4847 (7) 3 386 (4) 991 (6) 163 (10) 176 (10) 137 (18) All values are X lo4 except those for Pd, which are X lo5. The estimated standard deviations are given in parentheses. The temperature factor is of the form exp[-(pllha + P2Jc2 + P33Zz + Plzhk + p,,hl+ Pz3Jd)1.

W. L. Steffen and Gus J. Palenik

2436 Inorganic Chemistry, Vol. 15, No. 10, 1976 Table VI. Final Parameters of Hydrogen Atoms in PdCl,(dpm)a B , A' Dist, A Y z Atom X 3.9 1.06 123 303 Hl(1) 781 3.9 1.02 124 243 H2(1) 651 H(2a) 565 337 479 4.9 1.01 6.0 1.10 378 607 H(3a) 675 6.1 1.07 289 649 H(4a) 860 6.7 1.14 188 546 H(5a) 969 5.7 1.10 137 422 H(6a) 836 0.98 279 4.7 357 219 H(2b) 6.0 1.01 87 280 H(3b) 203 6.7 1.03 -68 353 H(4b) 239 6.6 1.07 421 447 -115 H(5b) 5.6 0.99 23 422 596 H(6b) 5.3 1.00 416 92 657 H(2c) 6.6 1.05 389 -34 H(3c) 678 6.6 1.11 215 -69 803 H(4c) 6.4 1.10 101 35 H(5c) 887 5.4 1.03 134 167 H(6c) 843 4.9 1.08 353 466 H(2d) 767 6.2 1.05 539 431 H(3d) 948 6.6 1.03 473 410 H(4d) 1146 6.6 1.01 363 299 H(5d) 1153 5.6 1.01 280 230 H(6d) 976 a The positional parameters are X103. The number in parentheses is the number of the carbon atom to which the hydrogen is bonded at a distance given in the last column. Table VII. Final Parameters of Hydrogen Atoms in PdCI, (dpe)CH,ClZa Atom X Y z B, A' 247 208 428 365 119 -60 -237 -260 -17 71 13 28 58 153 460 578 812 7 34 589 538 622 5 02 372 307

106 140 169 268 57 -34 31 200 274 215 307 464 522 429 362 468 45 0 38 1 306 127 2 -37 84 182

501 581 577 599 414 346 320 361 429 632 726 714 585 486 592 632 583 422 368 485 422 264 207 28 1

4.3 4.3 4.6 4.6 5.7 6.6 6.5 7.1 6.4 4.3 5.7 5.8 5.6 4.8 7.3 8.2 8.6 8.1 6.8 6.0 6.4 7.1 6.8 6.1

Table VIII. Final Parameters of Hydrogen Atoms in PdCl,(dpp)a Atom X Y z B, A' Dist, A -282 -301 -288 -475 -362 -500

-114 -3 -56 -182 65 -17 -65 -168 -82 167 269 266 363 322 237 159 335 446 565 541 388 475 460 209 -9 -4

28 1 314 124 162 85 154 295 191 56 13 106 368 5 39 66 3 618 45 6 28 -66 7 158 246 395 537 566 444 288

4.5 1-00 4.5 0.92 5.5 0.93 5.5 1.06 4.8 0.96 4.8 0.99 1 5.9 1.07 84 6.5 0.95 186 0.97 6.5 267 6.5 1.07 155 1.14 5.0 286 1.00 5.1 426 5.8 0.99 271 5.9 1.13 -17 6.4 1.03 -148 5.4 1.08 -175 0.97 5.3 -229 6.0 1.03 -334 6.0 0.97 -404 1.03 5.8 -379 4.6 1.00 -078 1.01 5.5 -174 1.04 6.4 -467 1.06 6.2 -659 7.4 1.00 -569 1.02 6.4 a The positional parameters are X lo3. The number in parentheses is the number of carbon atom to which the hydrogen is bonded at a distance given in the last column.

Dist, A 1.00 1.06 0.97 1.17 1.14 1.16 1.08 1.16 1.06 0.97 0.97 1.03 1.15 1.14 1.03 1.14 1.50 1.04 1.07 0.87 1.09 1.12 0.85 0.96

a The positional parameters are X l o 3 . The number in parentheses is the number of the carbon atom to which the hydrogen is

bonded at a distance given in the last column.

in the dpm complex involves the phosphorus atom which is closer to the PdC12 plane. Apparently, the large steric constraints in the dpm ligand prevent appropriate orbital overlap when the two Pd-P bonds are equal and coplanar with the PdC12 unit. Consequently, while a priori we might have expected the three diphosphine ligands to be identical electronically, the steric constraints imposed by chelation alter the interaction between the phosphorus and palladium atoms. The Pd-C1 bond distances in the three complexes should provide some indications of the electronic differences in the three ligands resulting from the steric constraints. The Pd-C1 bond is obviously sensitive to the nature of the trans atom as can be seen by the data in Table XI. The Pd-C1 bond is shortest when C1 or N is the trans atom while the longest

Table IX. Bond Lengths (A) for PdCl,(dpm), PdCl,(dpe).CH,Cl,, and PdCl,(dpp) with Their Estimated Standard Deviations in Parentheses Pd-Cl( 1) Pd-Cl(2) Pd-P(l) Pd-P(2) P(l)-CQ P(2)-CQ C(l)-C(2) C(2)-C(3) P(l)-C(la) P(l)-C(lb) P(2)-C(l c) P(2)-C( Id)

2.362 (1) 2.352 (1) 2.234 (1) 2.250 (1) 1.834 (3) 1.830 (3)

2.361 (2) 2.357 (2) 2.233 (2) 2.226 (2) 1.830 (8) 1.840 (7) 1.512 (11)

2.351 (1) 2.358 (2) 2.244 (1) 2.249 (2) 1.820 (5) 1.840 (4) 1.499 (7) 1.517 (9) 1.806 (3) 1.809 (7) 1.817 (7) 1.800 (3) 1.806 (7) 1.815 (4) 1.805 (3) 1.806 (8) 1.822 (6) 1.812 (4) 1.808 (8) 1.817 (5) a Carbon atom directly bonded to the phosphorus atom is given.

Pd-Cl bonds are found when P or u-bonded C ligands are the trans group. The variations of Pd-Cl distances shown in Table XI are in agreement with the trans-effect orderings obtained by other methods.33 Similar trends have also been reported for Pt-Cl bonds.34 In general the Pd-CI or Pt-Cl bond length decreases as the electronegativity of the trans atom increases. Whether these changes are related to u- or n-bonding effects (or a combination) is still controversial. We see that in the dpe case the two Pd-C1 bonds are not significantly different (as might be expected from the strain-free nature of the complex) and average 2.359 A. The Pd-C1 distances are in the region expected for a Pd-Cl bond trans to a Pd-P bond. Furthermore, the two C1-Pd-P angles are virtually identical. In the dpp complex the two Pd-Cl distances [2.351 (1) and 2.358 ( 2 ) A] are significantly different (to = 3.13) as are the various Cl-Pd-P angles (see Table X). However, the two Pd-C1 distances are sufficiently close to each that an average value of 2.354 A can be used for further discussion. We see that in going from the dpe to the dpp complex the average Pd-C1 distances decreases from 2.359 to 2.354 8, while the Pd-P distances increase from 2.230 to 2.246 A. Although the

+

Inorganic Chemistry, Vol. 15, No. 10, I976 2431

Palladium Chloride-Diphosphine Complexes Table X. Bond angles (deg) for PdCl,(dpm), PdCl,(dpe)CH,Cl,, and PdCl,(dpp) with Their Estimated Standard Deviations in Parentheses Cl(l)-Pd-C1(2) Cl(l)-Pd-P(l) C1(l)-Pd-P(2) C1(2)-Pd-P(1) C1(2)-Pd-P(2) P( l)-Pd-P(2) Pd-P( 1)-cy" Pd-P(1)-C(1a) Pd-P(1)-C(1b) Ca-P(1)-C(1a) Ca-P(1)-C(1b) C(1a)-P(1)-C(1b) Pd-P(2)-cy" Pd-P(Z)-C(lc) Pd-P(2>-C(ld) Ca-P(2)-C(lc) P-P(2)-C(ld) C(lc)-P(Z)-C(ld) P(l)-P-P(2) P(11-e-c C2?-P(2)

dPm 93.63 (3) 171.26 (3) 99.78 (3) 94.39 (3) 165.21 (3) 72.68 (3) 94.7 (1) 117.3 (1) 117.8 (1) 108.8 (1) 108.6 (1) 108.3 (1) 94.3 (1) 126.8 (1) 111.0 (1) 107.8 (1) 107.1 (1) 107.6 (1) 93.0 (1)

c-c-c

dPe 94.19 (7) 175.14 (7) 89.73 (7) 90.33 (7) 175.48 (7) 85.82 (7) 108.5 (2) 118.2 (2) 111.5 (2) 105.5 (3) 106.0 (3) 106.3 (3) 107.9 (2) 118.4 (3) 111.8 (2) 105.6 (4) 105.1 (3) 107.0 (4)

dpp 90.78 (5) 171.88 (5) 91.10 (5) 87.74 (5) 177.68 (5) 90.58 (5) 115.9 (2) 115.1 (2) 109.3 (2) 102.9 (2) 105.2 (2) 107.6 (2) 115.5 (2) 114.4 (2) 110.1 (2) 102.3 (2) 107.0 (2) 106.7 (2)

107.9 (5) 108.2 (5)

112.9 (4) 118.1 (4) 117.0 (5)

Carbon atom directly bonded to the phosphorus atom is given.

changes in the Pd-C1 distances are not significant, the slight decrease is consistent with the increase in the Pd-P distances. The Pd-Cl distances in the dpm complex present much the same dilemma that the Pd-P distances did, namely, the differences are highly significant (to = 7.1). The longer Pd-Cl(1) bond of 2.362 (1) A is trans to the shorter Pd-P(l) bond of 2.234 (1) A, in agreement with a trans effect. Strictly speaking, the opposite effect is seen in the dpp complex; however, the differences between the individual values are so

C(lb)

W

C(lb)

(b)

Figure 4. Views down the diphosphine ligand bonds, illustrating the eclipsed nature of various bonds: (a) down the C(1)-P(l) bond in PdCl,(dpm); (b) down the C(2)€(3) bond in PdCl,(dpp).

small that the assumption of equal Pd-P and Pd-C1 distances appears more reasonable. In summary, we could say that the dpe. ligand exerts a stronger trans influence than the dpp ligand and that the dpm case is much more complicated. Certainly, the maximum interaction between the phosphorus and palladium atoms occurs with the relatively strain-free dpe ligand. An important question is how the present results relate to our earlier study of the palladium thiocyanate complexes with

Table XI. Comparison of Pd-Cl Bond Distances as a Function of the Trans Atom Pd-Cl dist, A

Atom trans to C1 Coordination sphere

Compda

c1 C1 c1 C1 C1 c1 N N N N N C=C P

Ref

C1, C1, N, N PdC1, (cyclohexanone oxime), 14 2.24 C1, C1, Se, Se PdCl,(Et,Se), 15 2.266 (9) 2.28 C1, C1, N, N PdCI, (Ci0 H, NF, ) z 16 2.287 (2) c1, c1, s, s PdCl, (DMSO), 17 C1, C1, N, N PdCl, (nitrosobenzene), 18 2.295 (1) 2.30 (2) C1, C1, N, N PdC1, (acetoxime), 19 2.30 (1) C1, C1, N, N PdCl,(tetrahydrogen ethylenediaminetetraacetate)5H,O 20 C1, C1, N, S PdCl, (S-methyl-L-cysteine).H,0 21 2.305 (4) 2.307 (4) C1, C1, N, S PdC1, (S-methyl-L-cysteine).H,O 21 2.309 (5) C1, N, N, N PdCl(cpm)(cpmH) 22 2.31 Cl, C1, N, S PdCl,(methionine) 23 2.310(1) C1, C1, C=C, C=C PdCl,(norbornadiene) 24 2.311 (4) c1, c1, P, P PdCl, [ Ph,PCH,CH,P(CF3), 1 25 S C1, C1, S, N PdCl,(S-methyl-L-cysteine).H,O 21 2.312(7) 2.323 (1) C=C C1, C1, C=C, C=C PdCl,(norbornadiene) 24 2.324 (3) S C1, C1, S, N PdCl, (S-methyl-L-cysteine).H,O 21 2.327 (7) S c1, c1, s, c=c PdC1, [C3H,NHC(OMe)S] 26 2.331 (3) 27 N C1, N, N, N PdCl(Me,dpma) +C12.342 (6) 26 C=C c1, c1, s, c=c PdCl, [C, H,NHC(OMe)S] 2.35 S C1, C1, N, S PdCl, (methionine) 23 2.351 (1) This work P c1, c1, P, P PdCl,(dpp) This work 2.352 (1) P c1, c1, P, P PdCl,(dpm) This work 2.357 (2) P c1, c1, P, P PdCl,(dpe)~CH,Cl, 2.358 (2) This work P c1, c1, P, P PdCl,(dpp) This work 2.361 (2) P c1, c1, P, P PdCl,(dpe).CH,Cl, c1, c1, P, P cis-PdC1, (PPhMe,), 28 2.362 (3) P 2.362(1) P c1, c1, P, P PdCl,(dpm) This work c1, c1, P, P PdC1, [Ph,PN(C,H,)PPh,] 29 2.367 (3) P 2.370 (4) P c1, c1, P, P PdCl, [Ph,PCH,CH,P(CF,), ] 25 2.38 0-c c1, P, 0-c, c=c PdCl(PPh, )(methallyl) 30 2.381 (5) 0-C c1, P, P, a € trUnS-PdCl(PEt,), (C, H,N,) 31 2.45 U-C C1, N, N, U-C PdCl(Z-mdp)(mba) 32 Me,dpma = methyldi-[ (6-methyl-2-pyridyl)methyl]amine; 2-mdp = 2-methoxy-3-N,Ndimethylaminopropyl; Mba = ( S k methylbenzylamine; cpmH = 3,4'-bis(ethoxycarbonyl)-5-chloro-3',4,5'-trimethyldipyrromethene.

,

W. L. Steffen and Gus J. Palenik

2438 Inorganic Chemistry, Vol. 15, No. 10, 1976

agreement with slight differences in the two ligands. In summary, the P-C distances and endocyclic angles are consistent with the three ligands having about equal donor properties, with perhaps the dpe ligand having the best steric fit. A survey of the intermolecular distances less than 4.5 A in all cases did not reveal any short contacts which might influence the molecular dimensions. Similarly, a scan of intramolecular distances less than 4.0 A in the three complexes indicated that the majority of the shorter contacts involved the various hydrogen atoms and were not abnormally short. Therefore, the various results discussed above are not a direct consequence of any unusual inter- or intramolecular contact. Acknowledgment. We wish to thank the Center for Instructional and Research Activities, University of Florida, for a grant of computer time. Registry No. PdClz(dpm), 38425-01-3; PdClz(dpe).CH2CI2, 59831-01-5; PdClz(dpp), 59831-02-6.

Figure 5. Comparison of the geometry a b o u t t h e central Pd a t o m in six related diphosphine complexes: (a) Pd(SCN),(dpm), (b) PdCl,(dpm), (c) Pd(SCN)(NCS)(dpe), (d) PdCl,(dpe), (e) Pd(NCS),(dPP), (0PdCl,(dpp).

the three ligand^.^ The pertinent distances and angles in the six complexes are presented in Figure 5. We see that the P-Pd-P angle is dependent only on the ligand and the angles are virtually identical in the appropriate pairs. In addition, the asymmetry in the Pd-P bonds found in PdClz(dpm) of 0.016 8, is very close to the difference of 0.018 8, found in Pd(SCN)z(dpm), in agreement with steric constraints on the dpm ligand. Furthermore, the Pd-N and Pd-P distances are required by symmetry to be equal in the Pd(NCS)z(dpp) complex and for all practical purposes, the Pd-P and Pd-C1 bonds are equivalent in the PdClz(dpp) case. Finally, although the strongest Pd-P interaction occurs with the dpe ligand, the thiocyanate coordination is mixed with dpe as the ligand. Consequently, we conclude that our original observations regarding the role of steric effects on thiocyanate coordination in palladium complexes were indeed correct. The data in Figure 5 also illustrate the fact that the net electron density on the central palladium atom remains essentially constant, in essence, the electroneutrality principle.35 The two Pd-P distances in the dpp complexes are virtually the same and, of course, C1 and N have very similar trans-effect properties. The introduction of S-bonded thiocyanate in the dpe complex introduces the expected asymmetry in the Pd-P bonds but also causes both Pd-P bonds to increase relative to the PdCl2 case. Finally, in Pd(SCN)z(dpm) the Pd-P bonds are the longest found in any of the six complexes. Furthermore, since the Pd-S and Pd-C1 bond lengths are very similar, the longer Pd-P bonds in Pd(SCN)z(dpm) are probably not due to steric interactions. Presumably as the “better” or softer S donors are introduced into the coordination sphere, the Pd-P bond lengths increase to maintain an approximately constant charge density on the central Pd atom. There has been some discussion of the change in the endocyclic angle with a change in the electronegativity of the s u b ~ t i t u e n t .The ~ ~ ~average ~ ~ angles in the three complexes [120.0 (6)’ for dpm, 118.7 (7)O for dpe, and 118.8 (5)’ for dpp] are not significantly different from each other or from the average of 118.50 ( 9 ) O found in a large number of phosphorus-phenyl compounds.37 The average P-C(ring) bonds [1.806 (5) A for dpm, 1.807 ( 2 ) 8, for dpe, and 1.818 (3) & . for dpp] are all slightly smaller than the average of 1.828 (1) 8, found in 13 different compounds. The dpe value is significantly shorter than for the dpp case which is in

Supplementary Material Available: A comparison of observed and calculated structure factor amplitudes together with tables of the C-C distances and angles in the various phenyl rings (43 pages). Ordering information is given on a n y current masthead page.

References and Notes (1) Taken in part from the Ph.D. dissertation of W.L.S. submitted as partial requirements for the Ph.D. degree of the University of Florida, Aug 1975. (2) J. L. Burmeister and F. Basolo, Inorg. Chem., 3, 1587 (1964). (3) G. J. Palenik, M. Mathew, W. L. Steffen, and G. Beran, J . A m . Chem. Sot., 97, 1059 (1975). (4) One of the referees for ref 3 argued that since the bite changed, the

electronic properties of the three ligands would also vary. (5) J. E. Huheey and S. 0. Grim, Inorg. Nucl. Chem. Lett., 10,973 (1974),

also questioned our interpretation of the thiocyanate series. (6) J. A. A. Mokuolu, D. S. Payne, and J. C. Speakman, J . Chem. Soc., Dalton Trans., 1443 (1973). (7) J. R. Doyle, P. E. Slade, and H. B. Jonassen, Inorg. Synth., 6,216 (1960). (8) J. M. Jenkins and J. G. Verkade, Inorg. Synth., 11, 108 (1968). (9) H . Lipson and W. Cochran, “The Determination of Crystal Structures”, G. Bell and Sons Ltd., London, 1966, p 50. (IO) D. T. Cromer, A. C. Larson, and J. T. Waber, Acta Crystallogr., 17, 1044 (1964). (1 1) H. P. Hanson, F. Herman, J. D. Lea, and S. Skillman, Acta Crystallogr., 17. 1040 (1964). (1 2) R.~F. Stewart, E. R. Davidson, and W. T Simpson, J . Chem. Phys., 42, 3175 (1965). (13) Supplementary material. (14) M. Tanimura, T. Mizushima, and Y. Kinoshita, Bull. Chem. SOC. Jpn., 40, 2777 (1967). ( 1 5 ) P. E. Skakke and S. E. Rasmussen, Acta Chem. Stand., 24,2634 (1970). (16) Y. Kobayashi, A. Ohsawa, and Y. Iitaka, TetrahedronLett., 2643 (1973). (17) M. J. Bennett, F. A. Cotton, D. L. Weaver, R. J. Williams, and W. H. Watson, Acta Crystallogr., 23, 788 (1967). (18) R. G. Little and R. J. Doedens, Inorg. Chem., 12, 537 (1973). (19) Y. Kitano, K. Kobori, M. Tanimura, and Y. Kinoshita, Bull. Chem. SOC. Jpn., 47, 2969 (1974). 120) D. J. Robinson and C. H. L. Kennard. Chem. Commun.. 1236 (1967). (21) L. P. Battaglia, A. B. Corradi, C. G. Palmieri, M. Nardelli, and M. E. V. Tani, Acta Crystallogr., Sect. B, 29, 762 (1973). (22) F. C. March, J. E. Fergusson, and W. T. Robinson, J . Chem. Soc., Dalton Trans., 2069 (1972). (23) N. C. Stephenson, J. F. McConnell, and R. Warren, Inorg. Nucl. Chem. Lett., 3, 553 (1967). (24) . . N. C. Baenziger, G. F. Richards, and J. R. Doyle, Acta Crystallogr., 18, 924 (1965). (25) L. Manojlovic-Muir, D. Millington, K. W. Muir, D. W. A. Sharp, W. E. Hill. J. V. Ouagliano, and L. M. Vallarino, J . Chem. Soc., Chem. Commun., 999‘(1574). (26) P. Porta, J . Chem. SOC.A , 1217 (1971). (27) M. G. B. Drew, M. J. Riedl, and J. Rodgers, J. Chem. SOC.,Dalton Trans., 234 (1972). (28) L. L. Martin and R. A. Jacobson, Inorg. Chem., 10, 1795 (1971). (29) D. S. Payne, J. A. A. Mokuolu, and J. C. Speakman, Chem. Commun., 599 (1965). (30) R. Mason and D. R. Russell, Chem. Commun., 26 (1966). (31) R. W. Siekman and D. L. Weaver, Chem. Commun., 1021 (1968). (32) R. Claverini, A. De Renzi, P. Ganis, A. Panunzi, and C. Pedone, J . Organomet. Chem., 51, C30 (1973). (33) T. G. Appleton, H . C. Clark, and L. E. Manzer, Coord. Chem. Rev., 10, 335 (1973). (34) L. Manojlovic-Muir and K. W. Muir, Inorg. Chim. Acta, 10,47 (1974). (35) L. Pauling, “The Nature of the Chemical Bond’, 3d ed, Cornel1 University Press, Ithaca, N.Y., 1960. \ - ~ ,

~

Inorganic Chemistry, Vol. 15, No. IO, 1976 2439

Uranyl Nitrate Tetrahydrate-1 8-Crown-6 (36) A. Domenicano,A. Vaciago, and C. A. Coulson, Acta Crystallogr., Sect. B, 31, 221 (1975).

(37) A. Dominicano, A. Vaciago, and C. A. Coulson, Acta Crystallogr.,Sect. B, 31, 1630 (1975).

Contribution from Los Alamos Scientific Laboratory, University of California, Los Alamos, New Mexico 87545

Synthesis and Structure of the 1:1 Uranyl Nitrate Tetrahydrate-18-Crown-6 Compound, U O 2 ( N 0 3 ) 2 ( H 2 0 ) 2 * 2 H 2 0 - ( 18-Crown-6). Noncoordination of Uranyl by the Crown Ether P. G. ELLER* and R. A. PENNEMAN AIC60084U

Received February 3, 1976

The synthesis and crystal structure of UO2(NO3)2(H20)y2H20-( 18-crown-6), which forms from the reaction of uranyl nitrate hexahydrate and the cyclic polyether 18-crown-6, are reported. The uranyl group is not located within the crown ether group. Rather, the structure consists of neutral U02(N03)2(H20)2 units and separate crown ether molecules connected by hydrogen bonding through intermediary water molecules. The oxygens of the linear uranyl group are coordinated only to uranium; the eight-coordination of uranium is completed by six equatorial oxygen donors, two from waters and two from symmetrically bidentate nitrates. The uranium and the six uatorial oxygens are coplanar within 0.06 A. Pertinent distances are U-O(urany1) = 1.693 (6) A, U-O(water) = 2.434 U-O(nitrate) = 2.482 (6) and 2.486 (6) 8. The cyclic ether molecule-exists in the customary crown conformation with normal distances and angles. Crystal data are as follows: space group P1, Z = 1, a = 7.526 (7) A, b = 11.27 (1) A, c = 7.802 (4) A, 01 = 97.51 (6)O, j3 = 93.22 (6)O, y = 105.95 (6)O, RF = 0.058 for 2453 diffractometer-collected reflections with I 1 3 4 ) .

(53,

Introduction Crown ethers (cyclic polyethers) provide a cavity or cage which can be engineered to accommodate metal ions of different charge and Resulting complexes are of great synthetic interest since enhanced solubilities and reactivities of ionic materials in nonplar solvents often result. The complexes are also of considerable interest in regard to solvent extraction, isotope separation, and biological transport of metal ions. As a result, the synthesis and characterization of crown ether compounds are the subjects of intense interest in many laboratories. We have recently turned our attention to the possible utilization of crown ethers as a meahs of stabilizing unusual oxidation states and geometries in actinide complexes. The chelating ability of crown ethers with respect to alkali and alkaline earth metal ions is well documented, both crystallographically and ~hemically.~"In contrast, syntheses of only a few l a ~ ~ t h a n i d and e ~ ? actinidegJO ~ complexes have been reported, and structural verification of polyether complexation to these metals has hitherto been lacking. In this paper we report the synthesis and structure determination of a 1:l compound containing uranyl nitrate tetrahydrate and 18-cr0wn-6.~~ While this work was under way, the synthesis of the identical compound by a different method was r e p ~ r t e d .In ~ that preliminary report, spectroscopic data were interpreted to indicate that the nitrate groups were uncoordinated and the uranyl group lay within the ring of the six crown oxygen atoms. The x-ray structure determination described herein was undertaken to test the hypothesis of crown ether ligation. Experimental Section Preparation of U02(NO&(H20)2*2H20( 18-crown-6). Excellent crystals of the title compound were prepared in good yield by dissolving 2.70 g (5.4 mmol) of U02(N03)26H20 and 1.50 g (5.7'mmol) of 18-crown-6 in 90 ml of warm acetonitrile. The solution was allowed to stand overnight a t 10 OC, filtered, washed with a few milliliters of acetonitrile, and then vacuum-drid overflight at 25 OC to give 2.64 g (67% yield) of bright yellow needles of the title compound. The x-ray powder pattern, infrared spectrum, and decomposition point of the compound prepared by this method are indistinguishable from material prepared in ethan01.~ Anal. Calcd for UOlsN2C12H32: C, 19.73; H , 4.42; N, 3.84. Found: C, 20.22; H, 4.08; N, 3.67.

The compound is stable for days at 100 OC under 1 atm of N2. In an open capillary, the compound melts a t 140-147 OC with effervescence to a yellow liquid which resolidifies to a yellow powder by 160 OC and then gradually darkens above 265 OC. From a mixture of neat 18-crown-6 and U02(N03)y6H20 at 150 OC, the compound U0y1/2( 18-crown-6) forms, with properties identical with those of the above yellow powder. An@ Calcd: N , 0.00; C, 17.23; H, 2.89. Found: N, 0.00; C, 17.34; H, 2.91. X-Ray Data Collection. Optical examination and precession photographs failed to reveal any symmetry higher than triclinic. A parallelepiped of dimensions 0.06 X 0.08 X 0.14 mm was mounted approximately parallel to the long dimension of the crystal and 12 reflections with 20 in the range 33-44' were centered using an automated diffractometer and graphite-monochromatized Mo radiation (A 0.709 30 A). Least-squares refinement of the setting angles and orientation matrix gave the following cell: a = 7.526 (7) A, b = 11.27 (la A, c = 7.802 (4) A, 01 = 97.51 (6)O, j3 = 93.22 (6)O, y = 105.95 (6)". The unit cell thus chosen contains one formula unit (Pcalcd = 1.93 g ~ m - and ~ ) the large, medium, and small faces are of the forms (OOl), (loo], and (OlO),respectively. A data set was collected within the limiting hemisphere 1 5 20 5 60' by the 0-20 scan technique using a Picker FACS-I automated diffractometer equipped with a graphite monochromator (A 0.70930 A). A scan range of 2' plus a &dependent dispersion term and background counts of 20 s each were used. Of the 3143 unique reflections examined, 2453 were judged to be above background on the basis that I 1 3 4 where a(Z) = [ T B [0.015(T- B)]2]1/2,Tbeing the total count for each scan and B being the estimated background. The intensities of two standard reflections, measured after every 50 reflections, were found to decrease by ca. 8% during data collection, apparently due to crystal decomposition. An appropriate correction was applied using 8 polynomial determined by least-squares fitting the standard reflection curves. Lorentz and polarization corrections were applied in the usual way. Absorption corrections were applied11J2 (fi = 194.3 cm-l; transmission coefficients 0.21-0.35). Otherwise, the data collection and reduction were as previously described.13 Solution and Refmement of the Structure. The centric space group ( P l ) was initially chosen, an assumption supported by the successful refinement of the structure. With one formula unit pgr cell, the uranyl and crown ether groups each are required to possess 1 symmetry. The uranium atom was placed at the origin, and the carbon, nitrogen, and oxygen atoms were easily located with a difference Fourier synthesis. Neutral atom scattering factors were used for the light atems and hexavalent scattering factors for uranium. l 4 Anomalous dispersion terms were included for uranium.15 A conventional aqisotropic refinement of the 17 nonhydrogen atoms plus an overall scale factor

+ +